#include "blaswrap.h"
#include "f2c.h"

/* Subroutine */ int slatbs_(char *uplo, char *trans, char *diag, char *
	normin, integer *n, integer *kd, real *ab, integer *ldab, real *x, 
	real *scale, real *cnorm, integer *info)
{
/*  -- LAPACK auxiliary routine (version 3.0) --   
       Univ. of Tennessee, Univ. of California Berkeley, NAG Ltd.,   
       Courant Institute, Argonne National Lab, and Rice University   
       June 30, 1992   


    Purpose   
    =======   

    SLATBS solves one of the triangular systems   

       A *x = s*b  or  A'*x = s*b   

    with scaling to prevent overflow, where A is an upper or lower   
    triangular band matrix.  Here A' denotes the transpose of A, x and b   
    are n-element vectors, and s is a scaling factor, usually less than   
    or equal to 1, chosen so that the components of x will be less than   
    the overflow threshold.  If the unscaled problem will not cause   
    overflow, the Level 2 BLAS routine STBSV is called.  If the matrix A   
    is singular (A(j,j) = 0 for some j), then s is set to 0 and a   
    non-trivial solution to A*x = 0 is returned.   

    Arguments   
    =========   

    UPLO    (input) CHARACTER*1   
            Specifies whether the matrix A is upper or lower triangular.   
            = 'U':  Upper triangular   
            = 'L':  Lower triangular   

    TRANS   (input) CHARACTER*1   
            Specifies the operation applied to A.   
            = 'N':  Solve A * x = s*b  (No transpose)   
            = 'T':  Solve A'* x = s*b  (Transpose)   
            = 'C':  Solve A'* x = s*b  (Conjugate transpose = Transpose)   

    DIAG    (input) CHARACTER*1   
            Specifies whether or not the matrix A is unit triangular.   
            = 'N':  Non-unit triangular   
            = 'U':  Unit triangular   

    NORMIN  (input) CHARACTER*1   
            Specifies whether CNORM has been set or not.   
            = 'Y':  CNORM contains the column norms on entry   
            = 'N':  CNORM is not set on entry.  On exit, the norms will   
                    be computed and stored in CNORM.   

    N       (input) INTEGER   
            The order of the matrix A.  N >= 0.   

    KD      (input) INTEGER   
            The number of subdiagonals or superdiagonals in the   
            triangular matrix A.  KD >= 0.   

    AB      (input) REAL array, dimension (LDAB,N)   
            The upper or lower triangular band matrix A, stored in the   
            first KD+1 rows of the array. The j-th column of A is stored   
            in the j-th column of the array AB as follows:   
            if UPLO = 'U', AB(kd+1+i-j,j) = A(i,j) for max(1,j-kd)<=i<=j;   
            if UPLO = 'L', AB(1+i-j,j)    = A(i,j) for j<=i<=min(n,j+kd).   

    LDAB    (input) INTEGER   
            The leading dimension of the array AB.  LDAB >= KD+1.   

    X       (input/output) REAL array, dimension (N)   
            On entry, the right hand side b of the triangular system.   
            On exit, X is overwritten by the solution vector x.   

    SCALE   (output) REAL   
            The scaling factor s for the triangular system   
               A * x = s*b  or  A'* x = s*b.   
            If SCALE = 0, the matrix A is singular or badly scaled, and   
            the vector x is an exact or approximate solution to A*x = 0.   

    CNORM   (input or output) REAL array, dimension (N)   

            If NORMIN = 'Y', CNORM is an input argument and CNORM(j)   
            contains the norm of the off-diagonal part of the j-th column   
            of A.  If TRANS = 'N', CNORM(j) must be greater than or equal   
            to the infinity-norm, and if TRANS = 'T' or 'C', CNORM(j)   
            must be greater than or equal to the 1-norm.   

            If NORMIN = 'N', CNORM is an output argument and CNORM(j)   
            returns the 1-norm of the offdiagonal part of the j-th column   
            of A.   

    INFO    (output) INTEGER   
            = 0:  successful exit   
            < 0:  if INFO = -k, the k-th argument had an illegal value   

    Further Details   
    ======= =======   

    A rough bound on x is computed; if that is less than overflow, STBSV   
    is called, otherwise, specific code is used which checks for possible   
    overflow or divide-by-zero at every operation.   

    A columnwise scheme is used for solving A*x = b.  The basic algorithm   
    if A is lower triangular is   

         x[1:n] := b[1:n]   
         for j = 1, ..., n   
              x(j) := x(j) / A(j,j)   
              x[j+1:n] := x[j+1:n] - x(j) * A[j+1:n,j]   
         end   

    Define bounds on the components of x after j iterations of the loop:   
       M(j) = bound on x[1:j]   
       G(j) = bound on x[j+1:n]   
    Initially, let M(0) = 0 and G(0) = max{x(i), i=1,...,n}.   

    Then for iteration j+1 we have   
       M(j+1) <= G(j) / | A(j+1,j+1) |   
       G(j+1) <= G(j) + M(j+1) * | A[j+2:n,j+1] |   
              <= G(j) ( 1 + CNORM(j+1) / | A(j+1,j+1) | )   

    where CNORM(j+1) is greater than or equal to the infinity-norm of   
    column j+1 of A, not counting the diagonal.  Hence   

       G(j) <= G(0) product ( 1 + CNORM(i) / | A(i,i) | )   
                    1<=i<=j   
    and   

       |x(j)| <= ( G(0) / |A(j,j)| ) product ( 1 + CNORM(i) / |A(i,i)| )   
                                     1<=i< j   

    Since |x(j)| <= M(j), we use the Level 2 BLAS routine STBSV if the   
    reciprocal of the largest M(j), j=1,..,n, is larger than   
    max(underflow, 1/overflow).   

    The bound on x(j) is also used to determine when a step in the   
    columnwise method can be performed without fear of overflow.  If   
    the computed bound is greater than a large constant, x is scaled to   
    prevent overflow, but if the bound overflows, x is set to 0, x(j) to   
    1, and scale to 0, and a non-trivial solution to A*x = 0 is found.   

    Similarly, a row-wise scheme is used to solve A'*x = b.  The basic   
    algorithm for A upper triangular is   

         for j = 1, ..., n   
              x(j) := ( b(j) - A[1:j-1,j]' * x[1:j-1] ) / A(j,j)   
         end   

    We simultaneously compute two bounds   
         G(j) = bound on ( b(i) - A[1:i-1,i]' * x[1:i-1] ), 1<=i<=j   
         M(j) = bound on x(i), 1<=i<=j   

    The initial values are G(0) = 0, M(0) = max{b(i), i=1,..,n}, and we   
    add the constraint G(j) >= G(j-1) and M(j) >= M(j-1) for j >= 1.   
    Then the bound on x(j) is   

         M(j) <= M(j-1) * ( 1 + CNORM(j) ) / | A(j,j) |   

              <= M(0) * product ( ( 1 + CNORM(i) ) / |A(i,i)| )   
                        1<=i<=j   

    and we can safely call STBSV if 1/M(n) and 1/G(n) are both greater   
    than max(underflow, 1/overflow).   

    =====================================================================   


       Parameter adjustments */
    /* Table of constant values */
    static integer c__1 = 1;
    static real c_b36 = .5f;
    
    /* System generated locals */
    integer ab_dim1, ab_offset, i__1, i__2, i__3, i__4;
    real r__1, r__2, r__3;
    /* Local variables */
    static integer jinc, jlen;
    static real xbnd;
    static integer imax;
    static real tmax, tjjs;
    extern doublereal sdot_(integer *, real *, integer *, real *, integer *);
    static real xmax, grow, sumj;
    static integer i__, j, maind;
    extern logical lsame_(char *, char *);
    extern /* Subroutine */ int sscal_(integer *, real *, real *, integer *);
    static real tscal, uscal;
    static integer jlast;
    extern doublereal sasum_(integer *, real *, integer *);
    static logical upper;
    extern /* Subroutine */ int stbsv_(char *, char *, char *, integer *, 
	    integer *, real *, integer *, real *, integer *), saxpy_(integer *, real *, real *, integer *, real *, 
	    integer *);
    static real xj;
    extern doublereal slamch_(char *);
    extern /* Subroutine */ int xerbla_(char *, integer *);
    static real bignum;
    extern integer isamax_(integer *, real *, integer *);
    static logical notran;
    static integer jfirst;
    static real smlnum;
    static logical nounit;
    static real rec, tjj;
#define ab_ref(a_1,a_2) ab[(a_2)*ab_dim1 + a_1]


    ab_dim1 = *ldab;
    ab_offset = 1 + ab_dim1 * 1;
    ab -= ab_offset;
    --x;
    --cnorm;

    /* Function Body */
    *info = 0;
    upper = lsame_(uplo, "U");
    notran = lsame_(trans, "N");
    nounit = lsame_(diag, "N");

/*     Test the input parameters. */

    if (! upper && ! lsame_(uplo, "L")) {
	*info = -1;
    } else if (! notran && ! lsame_(trans, "T") && ! 
	    lsame_(trans, "C")) {
	*info = -2;
    } else if (! nounit && ! lsame_(diag, "U")) {
	*info = -3;
    } else if (! lsame_(normin, "Y") && ! lsame_(normin,
	     "N")) {
	*info = -4;
    } else if (*n < 0) {
	*info = -5;
    } else if (*kd < 0) {
	*info = -6;
    } else if (*ldab < *kd + 1) {
	*info = -8;
    }
    if (*info != 0) {
	i__1 = -(*info);
	xerbla_("SLATBS", &i__1);
	return 0;
    }

/*     Quick return if possible */

    if (*n == 0) {
	return 0;
    }

/*     Determine machine dependent parameters to control overflow. */

    smlnum = slamch_("Safe minimum") / slamch_("Precision");
    bignum = 1.f / smlnum;
    *scale = 1.f;

    if (lsame_(normin, "N")) {

/*        Compute the 1-norm of each column, not including the diagonal. */

	if (upper) {

/*           A is upper triangular. */

	    i__1 = *n;
	    for (j = 1; j <= i__1; ++j) {
/* Computing MIN */
		i__2 = *kd, i__3 = j - 1;
		jlen = min(i__2,i__3);
		cnorm[j] = sasum_(&jlen, &ab_ref(*kd + 1 - jlen, j), &c__1);
/* L10: */
	    }
	} else {

/*           A is lower triangular. */

	    i__1 = *n;
	    for (j = 1; j <= i__1; ++j) {
/* Computing MIN */
		i__2 = *kd, i__3 = *n - j;
		jlen = min(i__2,i__3);
		if (jlen > 0) {
		    cnorm[j] = sasum_(&jlen, &ab_ref(2, j), &c__1);
		} else {
		    cnorm[j] = 0.f;
		}
/* L20: */
	    }
	}
    }

/*     Scale the column norms by TSCAL if the maximum element in CNORM is   
       greater than BIGNUM. */

    imax = isamax_(n, &cnorm[1], &c__1);
    tmax = cnorm[imax];
    if (tmax <= bignum) {
	tscal = 1.f;
    } else {
	tscal = 1.f / (smlnum * tmax);
	sscal_(n, &tscal, &cnorm[1], &c__1);
    }

/*     Compute a bound on the computed solution vector to see if the   
       Level 2 BLAS routine STBSV can be used. */

    j = isamax_(n, &x[1], &c__1);
    xmax = (r__1 = x[j], dabs(r__1));
    xbnd = xmax;
    if (notran) {

/*        Compute the growth in A * x = b. */

	if (upper) {
	    jfirst = *n;
	    jlast = 1;
	    jinc = -1;
	    maind = *kd + 1;
	} else {
	    jfirst = 1;
	    jlast = *n;
	    jinc = 1;
	    maind = 1;
	}

	if (tscal != 1.f) {
	    grow = 0.f;
	    goto L50;
	}

	if (nounit) {

/*           A is non-unit triangular.   

             Compute GROW = 1/G(j) and XBND = 1/M(j).   
             Initially, G(0) = max{x(i), i=1,...,n}. */

	    grow = 1.f / dmax(xbnd,smlnum);
	    xbnd = grow;
	    i__1 = jlast;
	    i__2 = jinc;
	    for (j = jfirst; i__2 < 0 ? j >= i__1 : j <= i__1; j += i__2) {

/*              Exit the loop if the growth factor is too small. */

		if (grow <= smlnum) {
		    goto L50;
		}

/*              M(j) = G(j-1) / abs(A(j,j)) */

		tjj = (r__1 = ab_ref(maind, j), dabs(r__1));
/* Computing MIN */
		r__1 = xbnd, r__2 = dmin(1.f,tjj) * grow;
		xbnd = dmin(r__1,r__2);
		if (tjj + cnorm[j] >= smlnum) {

/*                 G(j) = G(j-1)*( 1 + CNORM(j) / abs(A(j,j)) ) */

		    grow *= tjj / (tjj + cnorm[j]);
		} else {

/*                 G(j) could overflow, set GROW to 0. */

		    grow = 0.f;
		}
/* L30: */
	    }
	    grow = xbnd;
	} else {

/*           A is unit triangular.   

             Compute GROW = 1/G(j), where G(0) = max{x(i), i=1,...,n}.   

   Computing MIN */
	    r__1 = 1.f, r__2 = 1.f / dmax(xbnd,smlnum);
	    grow = dmin(r__1,r__2);
	    i__2 = jlast;
	    i__1 = jinc;
	    for (j = jfirst; i__1 < 0 ? j >= i__2 : j <= i__2; j += i__1) {

/*              Exit the loop if the growth factor is too small. */

		if (grow <= smlnum) {
		    goto L50;
		}

/*              G(j) = G(j-1)*( 1 + CNORM(j) ) */

		grow *= 1.f / (cnorm[j] + 1.f);
/* L40: */
	    }
	}
L50:

	;
    } else {

/*        Compute the growth in A' * x = b. */

	if (upper) {
	    jfirst = 1;
	    jlast = *n;
	    jinc = 1;
	    maind = *kd + 1;
	} else {
	    jfirst = *n;
	    jlast = 1;
	    jinc = -1;
	    maind = 1;
	}

	if (tscal != 1.f) {
	    grow = 0.f;
	    goto L80;
	}

	if (nounit) {

/*           A is non-unit triangular.   

             Compute GROW = 1/G(j) and XBND = 1/M(j).   
             Initially, M(0) = max{x(i), i=1,...,n}. */

	    grow = 1.f / dmax(xbnd,smlnum);
	    xbnd = grow;
	    i__1 = jlast;
	    i__2 = jinc;
	    for (j = jfirst; i__2 < 0 ? j >= i__1 : j <= i__1; j += i__2) {

/*              Exit the loop if the growth factor is too small. */

		if (grow <= smlnum) {
		    goto L80;
		}

/*              G(j) = max( G(j-1), M(j-1)*( 1 + CNORM(j) ) ) */

		xj = cnorm[j] + 1.f;
/* Computing MIN */
		r__1 = grow, r__2 = xbnd / xj;
		grow = dmin(r__1,r__2);

/*              M(j) = M(j-1)*( 1 + CNORM(j) ) / abs(A(j,j)) */

		tjj = (r__1 = ab_ref(maind, j), dabs(r__1));
		if (xj > tjj) {
		    xbnd *= tjj / xj;
		}
/* L60: */
	    }
	    grow = dmin(grow,xbnd);
	} else {

/*           A is unit triangular.   

             Compute GROW = 1/G(j), where G(0) = max{x(i), i=1,...,n}.   

   Computing MIN */
	    r__1 = 1.f, r__2 = 1.f / dmax(xbnd,smlnum);
	    grow = dmin(r__1,r__2);
	    i__2 = jlast;
	    i__1 = jinc;
	    for (j = jfirst; i__1 < 0 ? j >= i__2 : j <= i__2; j += i__1) {

/*              Exit the loop if the growth factor is too small. */

		if (grow <= smlnum) {
		    goto L80;
		}

/*              G(j) = ( 1 + CNORM(j) )*G(j-1) */

		xj = cnorm[j] + 1.f;
		grow /= xj;
/* L70: */
	    }
	}
L80:
	;
    }

    if (grow * tscal > smlnum) {

/*        Use the Level 2 BLAS solve if the reciprocal of the bound on   
          elements of X is not too small. */

	stbsv_(uplo, trans, diag, n, kd, &ab[ab_offset], ldab, &x[1], &c__1);
    } else {

/*        Use a Level 1 BLAS solve, scaling intermediate results. */

	if (xmax > bignum) {

/*           Scale X so that its components are less than or equal to   
             BIGNUM in absolute value. */

	    *scale = bignum / xmax;
	    sscal_(n, scale, &x[1], &c__1);
	    xmax = bignum;
	}

	if (notran) {

/*           Solve A * x = b */

	    i__1 = jlast;
	    i__2 = jinc;
	    for (j = jfirst; i__2 < 0 ? j >= i__1 : j <= i__1; j += i__2) {

/*              Compute x(j) = b(j) / A(j,j), scaling x if necessary. */

		xj = (r__1 = x[j], dabs(r__1));
		if (nounit) {
		    tjjs = ab_ref(maind, j) * tscal;
		} else {
		    tjjs = tscal;
		    if (tscal == 1.f) {
			goto L95;
		    }
		}
		tjj = dabs(tjjs);
		if (tjj > smlnum) {

/*                    abs(A(j,j)) > SMLNUM: */

		    if (tjj < 1.f) {
			if (xj > tjj * bignum) {

/*                          Scale x by 1/b(j). */

			    rec = 1.f / xj;
			    sscal_(n, &rec, &x[1], &c__1);
			    *scale *= rec;
			    xmax *= rec;
			}
		    }
		    x[j] /= tjjs;
		    xj = (r__1 = x[j], dabs(r__1));
		} else if (tjj > 0.f) {

/*                    0 < abs(A(j,j)) <= SMLNUM: */

		    if (xj > tjj * bignum) {

/*                       Scale x by (1/abs(x(j)))*abs(A(j,j))*BIGNUM   
                         to avoid overflow when dividing by A(j,j). */

			rec = tjj * bignum / xj;
			if (cnorm[j] > 1.f) {

/*                          Scale by 1/CNORM(j) to avoid overflow when   
                            multiplying x(j) times column j. */

			    rec /= cnorm[j];
			}
			sscal_(n, &rec, &x[1], &c__1);
			*scale *= rec;
			xmax *= rec;
		    }
		    x[j] /= tjjs;
		    xj = (r__1 = x[j], dabs(r__1));
		} else {

/*                    A(j,j) = 0:  Set x(1:n) = 0, x(j) = 1, and   
                      scale = 0, and compute a solution to A*x = 0. */

		    i__3 = *n;
		    for (i__ = 1; i__ <= i__3; ++i__) {
			x[i__] = 0.f;
/* L90: */
		    }
		    x[j] = 1.f;
		    xj = 1.f;
		    *scale = 0.f;
		    xmax = 0.f;
		}
L95:

/*              Scale x if necessary to avoid overflow when adding a   
                multiple of column j of A. */

		if (xj > 1.f) {
		    rec = 1.f / xj;
		    if (cnorm[j] > (bignum - xmax) * rec) {

/*                    Scale x by 1/(2*abs(x(j))). */

			rec *= .5f;
			sscal_(n, &rec, &x[1], &c__1);
			*scale *= rec;
		    }
		} else if (xj * cnorm[j] > bignum - xmax) {

/*                 Scale x by 1/2. */

		    sscal_(n, &c_b36, &x[1], &c__1);
		    *scale *= .5f;
		}

		if (upper) {
		    if (j > 1) {

/*                    Compute the update   
                         x(max(1,j-kd):j-1) := x(max(1,j-kd):j-1) -   
                                               x(j)* A(max(1,j-kd):j-1,j)   

   Computing MIN */
			i__3 = *kd, i__4 = j - 1;
			jlen = min(i__3,i__4);
			r__1 = -x[j] * tscal;
			saxpy_(&jlen, &r__1, &ab_ref(*kd + 1 - jlen, j), &
				c__1, &x[j - jlen], &c__1);
			i__3 = j - 1;
			i__ = isamax_(&i__3, &x[1], &c__1);
			xmax = (r__1 = x[i__], dabs(r__1));
		    }
		} else if (j < *n) {

/*                 Compute the update   
                      x(j+1:min(j+kd,n)) := x(j+1:min(j+kd,n)) -   
                                            x(j) * A(j+1:min(j+kd,n),j)   

   Computing MIN */
		    i__3 = *kd, i__4 = *n - j;
		    jlen = min(i__3,i__4);
		    if (jlen > 0) {
			r__1 = -x[j] * tscal;
			saxpy_(&jlen, &r__1, &ab_ref(2, j), &c__1, &x[j + 1], 
				&c__1);
		    }
		    i__3 = *n - j;
		    i__ = j + isamax_(&i__3, &x[j + 1], &c__1);
		    xmax = (r__1 = x[i__], dabs(r__1));
		}
/* L100: */
	    }

	} else {

/*           Solve A' * x = b */

	    i__2 = jlast;
	    i__1 = jinc;
	    for (j = jfirst; i__1 < 0 ? j >= i__2 : j <= i__2; j += i__1) {

/*              Compute x(j) = b(j) - sum A(k,j)*x(k).   
                                      k<>j */

		xj = (r__1 = x[j], dabs(r__1));
		uscal = tscal;
		rec = 1.f / dmax(xmax,1.f);
		if (cnorm[j] > (bignum - xj) * rec) {

/*                 If x(j) could overflow, scale x by 1/(2*XMAX). */

		    rec *= .5f;
		    if (nounit) {
			tjjs = ab_ref(maind, j) * tscal;
		    } else {
			tjjs = tscal;
		    }
		    tjj = dabs(tjjs);
		    if (tjj > 1.f) {

/*                       Divide by A(j,j) when scaling x if A(j,j) > 1.   

   Computing MIN */
			r__1 = 1.f, r__2 = rec * tjj;
			rec = dmin(r__1,r__2);
			uscal /= tjjs;
		    }
		    if (rec < 1.f) {
			sscal_(n, &rec, &x[1], &c__1);
			*scale *= rec;
			xmax *= rec;
		    }
		}

		sumj = 0.f;
		if (uscal == 1.f) {

/*                 If the scaling needed for A in the dot product is 1,   
                   call SDOT to perform the dot product. */

		    if (upper) {
/* Computing MIN */
			i__3 = *kd, i__4 = j - 1;
			jlen = min(i__3,i__4);
			sumj = sdot_(&jlen, &ab_ref(*kd + 1 - jlen, j), &c__1,
				 &x[j - jlen], &c__1);
		    } else {
/* Computing MIN */
			i__3 = *kd, i__4 = *n - j;
			jlen = min(i__3,i__4);
			if (jlen > 0) {
			    sumj = sdot_(&jlen, &ab_ref(2, j), &c__1, &x[j + 
				    1], &c__1);
			}
		    }
		} else {

/*                 Otherwise, use in-line code for the dot product. */

		    if (upper) {
/* Computing MIN */
			i__3 = *kd, i__4 = j - 1;
			jlen = min(i__3,i__4);
			i__3 = jlen;
			for (i__ = 1; i__ <= i__3; ++i__) {
			    sumj += ab_ref(*kd + i__ - jlen, j) * uscal * x[j 
				    - jlen - 1 + i__];
/* L110: */
			}
		    } else {
/* Computing MIN */
			i__3 = *kd, i__4 = *n - j;
			jlen = min(i__3,i__4);
			i__3 = jlen;
			for (i__ = 1; i__ <= i__3; ++i__) {
			    sumj += ab_ref(i__ + 1, j) * uscal * x[j + i__];
/* L120: */
			}
		    }
		}

		if (uscal == tscal) {

/*                 Compute x(j) := ( x(j) - sumj ) / A(j,j) if 1/A(j,j)   
                   was not used to scale the dotproduct. */

		    x[j] -= sumj;
		    xj = (r__1 = x[j], dabs(r__1));
		    if (nounit) {

/*                    Compute x(j) = x(j) / A(j,j), scaling if necessary. */

			tjjs = ab_ref(maind, j) * tscal;
		    } else {
			tjjs = tscal;
			if (tscal == 1.f) {
			    goto L135;
			}
		    }
		    tjj = dabs(tjjs);
		    if (tjj > smlnum) {

/*                       abs(A(j,j)) > SMLNUM: */

			if (tjj < 1.f) {
			    if (xj > tjj * bignum) {

/*                             Scale X by 1/abs(x(j)). */

				rec = 1.f / xj;
				sscal_(n, &rec, &x[1], &c__1);
				*scale *= rec;
				xmax *= rec;
			    }
			}
			x[j] /= tjjs;
		    } else if (tjj > 0.f) {

/*                       0 < abs(A(j,j)) <= SMLNUM: */

			if (xj > tjj * bignum) {

/*                          Scale x by (1/abs(x(j)))*abs(A(j,j))*BIGNUM. */

			    rec = tjj * bignum / xj;
			    sscal_(n, &rec, &x[1], &c__1);
			    *scale *= rec;
			    xmax *= rec;
			}
			x[j] /= tjjs;
		    } else {

/*                       A(j,j) = 0:  Set x(1:n) = 0, x(j) = 1, and   
                         scale = 0, and compute a solution to A'*x = 0. */

			i__3 = *n;
			for (i__ = 1; i__ <= i__3; ++i__) {
			    x[i__] = 0.f;
/* L130: */
			}
			x[j] = 1.f;
			*scale = 0.f;
			xmax = 0.f;
		    }
L135:
		    ;
		} else {

/*                 Compute x(j) := x(j) / A(j,j) - sumj if the dot   
                   product has already been divided by 1/A(j,j). */

		    x[j] = x[j] / tjjs - sumj;
		}
/* Computing MAX */
		r__2 = xmax, r__3 = (r__1 = x[j], dabs(r__1));
		xmax = dmax(r__2,r__3);
/* L140: */
	    }
	}
	*scale /= tscal;
    }

/*     Scale the column norms by 1/TSCAL for return. */

    if (tscal != 1.f) {
	r__1 = 1.f / tscal;
	sscal_(n, &r__1, &cnorm[1], &c__1);
    }

    return 0;

/*     End of SLATBS */

} /* slatbs_ */

#undef ab_ref


